Collecting and annotating transformation tools for use in generating transformation programs

ABSTRACT

Methods, computer systems, computer-storage media, and graphical user interfaces are provided for facilitating data transformations, according to embodiments of the present invention. In one embodiment, a plurality of remote sources is searched to identify candidate transformation tools relevant for performing data transformations. The candidate transformation tools are analyzed to identify tool examples corresponding with each of the candidate transformation tools. For each of the candidate transformation tools, the tool examples are stored in association with the corresponding candidate transformation tool. Based on a comparison of tool examples with example values, a transformation tool is identified as relevant to facilitate transforming example input values to the desired form in which to transform data.

BACKGROUND

Data analysts oftentimes desire to transform a set of data values to aparticular data format (also sometimes referred to as data wrangling).For example, data may be collected in various formats or variations. Toeffectively analyze or consume the data, however, the collected data isdesired to be transformed to a standard or common format. Upontransforming the diverse data to a consistent format, such transformeddata can be analyzed (e.g., to collect statistics). Example datatransformations include, for example, date-time conversions, addressparsing, name conversions, etc.

Performing data transformations, however, is often difficult and timeconsuming. For example, because data might be collected in numerous,diverse formats, a different transformation may be applied to each ofthe different format types and, as such, result in an extensive amountof time to perform each of the transformations. In particular, a usermay be required to manually search for, or develop, a datatransformation operation or set of data transformation operations toapply to a collected data set in order to accomplish a uniform set ofdata values. In order to more efficiently perform data transformations,it is important that a user be able to effectively search for and/orutilize transformation operations that transform data as desired by theuser.

SUMMARY

This Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used as an aid in determining the scope of the claimed subjectmatter.

Various aspects of the technology described herein are generallydirected to systems, methods, and computer storage media for, amongother things, facilitating data transformations. Generally,transformation programs that perform data transformations can bedynamically generated based on example input and/or output values, forinstance, provided via a user device. Based on the example values, atransformation engine can search a collection of transformation tools,such as transformation functions, to identify tools that can performdata transformations generally related to a desired data transformation.In some cases, a supplemental tool, such as a function, table, syntacticoperator, or web service, can be used along with the initiallyidentified transformation tool to generate a transformation program.Generated transformation programs can be ranked and provided assuggestions for performing data transformations. Based on a selection ofa transformation program, the transformation program can be executed toproduce transformed output values.

BRIEF DESCRIPTION OF THE DRAWINGS

The technology described herein is described in detail below withreference to the attached drawing figures, wherein:

FIG. 1 is a block diagram of an exemplary computing environment suitablefor use in implementing aspects of the technology described herein;

FIG. 2 is a block diagram of an exemplary system for facilitating datatransformations, suitable for use in implementing aspects of thetechnology described herein;

FIG. 3 is an exemplary graphical user interface associated with a datatransformation, in accordance with aspects of the technology describedherein;

FIG. 4 is an example transformation engine in accordance with aspects ofthe technology described herein;

FIG. 5 is an exemplary graphical user interface enabling a user to inputone or more transformation tools or sources, in accordance with aspectsof the technology described herein;

FIG. 6 provides an example of a data transformer environment, inaccordance with aspects of the technology described herein;

FIG. 7 provides another exemplary graphical user interface associatedwith a data transformation, in accordance with aspects of the technologydescribed herein;

FIGS. 8A-8B provide another exemplary graphical user interfaceassociated with a data transformation, in accordance with aspects of thetechnology described herein;

FIG. 9A-9B provide another exemplary graphical user interface associatedwith a data transformation, in accordance with aspects of the technologydescribed herein;

FIG. 10 is a flow diagram that illustrates an exemplary methodimplementing data transformations at a user device, in accordance withaspects of the technology described herein;

FIG. 11 is a flow diagram that illustrates another exemplary methodimplementing data transformations at a user device, in accordance withan aspect of the technology described herein;

FIG. 12 is a flow diagram that illustrates an exemplary method ofimplementing data transformations, in accordance with an aspect of thetechnology described herein;

FIG. 13 is a flow diagram that illustrates another exemplary method ofimplementing data transformations, in accordance with an aspect of thetechnology described herein;

FIG. 14 is a flow diagram that illustrates an exemplary method forcollecting transformation tools, in accordance with an aspect of thetechnology described herein;

FIG. 15 is a flow diagram that illustrates an exemplary method forgenerating transformation tools, in accordance with an aspect of thetechnology described herein;

FIG. 16 is a flow diagram that illustrates another exemplary method forgenerating transformation tools, in accordance with an aspect of thetechnology described herein;

FIG. 17 is a flow diagram that illustrates an exemplary method forannotating transformation tools, in accordance with an aspect of thetechnology described herein;

FIG. 18 is a flow diagram that illustrates an exemplary method forannotating transformation tools via static analysis, in accordance withan aspect of the technology described herein;

FIG. 19 is a flow diagram that illustrates an exemplary method forannotating transformation tools via dynamic analysis, in accordance withan aspect of the technology described herein;

FIG. 20 is a flow diagram that illustrates an exemplary method forgenerating an index, in accordance with an aspect of the technologydescribed herein;

FIG. 21 is a flow diagram that illustrates another exemplary method forgenerating an index, in accordance with an aspect of the technologydescribed herein;

FIG. 22 is a flow diagram that illustrates an exemplary method forgenerating and providing transformation programs, in accordance with anaspect of the technology described herein;

FIG. 23 is a flow diagram that illustrates an exemplary method forgenerating and providing transformation programs using transformationfunctions, in accordance with an aspect of the technology describedherein;

FIG. 24 is a flow diagram that illustrates an exemplary method foridentifying relevant transformation tools using syntactic distance, inaccordance with an aspect of the technology described herein;

FIG. 25 is a flow diagram that illustrates an exemplary method forefficiently generating a transformation program, in accordance with anaspect of the technology described herein;

FIG. 26 is a flow diagram that illustrates an exemplary method forfacilitating extensible data transformations, in accordance with anaspect of the technology described herein; and

FIG. 27 is a flow diagram that illustrates another exemplary method forfacilitating extensible data transformations, in accordance with anaspect of the technology described herein.

DETAILED DESCRIPTION

The technology described herein is described with specificity to meetstatutory requirements. However, the description itself is not intendedto limit the scope of this patent. Rather, the inventors havecontemplated that the claimed subject matter might also be embodied inother ways, to include different steps or combinations of steps similarto the ones described in this document, in conjunction with otherpresent or future technologies. Moreover, although the terms “step” and“block” may be used herein to connote different elements of methodsemployed, the terms should not be interpreted as implying any particularorder among or between various steps herein disclosed unless and exceptwhen the order of individual steps is explicitly described.

Various aspects of the technology described herein are generallydirected to systems, methods, and computer storage media for, amongother things, facilitating data transformations. Generally, at a highlevel, existing transformation tools that can be used to transform datacan be collected and annotated. In particular, for instance, the web oran enterprise can be crawled to identify existing transformation toolsthat might be candidates for subsequent use in performing datatransformations. Upon identifying such candidate transformation tools,the tools can be analyzed to identify characteristics or attributesassociated with the tools, or the source from which the tools wereidentified. For instance, source code associated with transformationfunctions can be statically or dynamically analyzed to identify callingexamples that can be input and/or output from the transformationfunction.

In accordance with receiving example values, such as example inputvalues and example output values selected by a user, a transformationengine can use the annotations to search for transformation tools thatare relevant to a desired data transformation. Any number of methods canbe used to search for relevant transformation tools. Upon identifyingand, in some cases, ranking transformation tools, tools deemed relevantcan be used to generate a transformation program that can perform a datatransformation. As can be appreciated, in many cases, existingtransformation tools (e.g., transformation functions) alone do notperform the desired data transformation. Accordingly, supplementaltransformation tools, such as functions, tables, services, and operatorscan be identified and applied in connection with the initiallyidentified transformation tool to generate transformation programs. Suchtransformation programs can be ranked, for instance, based on attributesof the underlying transformation tools or sources associated therewith.In some cases, suggestions of the transformation programs can beprovided to the user device for user selection of one of thetransformation programs. Additionally or alternatively, transformedoutput values resulting from execution of a transformation program canbe provided to the user device.

Accordingly, in one aspect of the present invention, a computing systemhaving a processor; and computer storage memory havingcomputer-executable instructions stored thereon which, when executed bythe processor, configure the computing system to facilitate datatransformations using a set of example values including one or moreexample input values that indicate data values to be transformed and oneor more example output values that indicate a desired form in which totransform data is provided. In one embodiment, the computer systemsearches a plurality of remote sources to identify candidatetransformation tools relevant for performing data transformations. Thecomputer system further analyzes the candidate transformation tools toidentify one or more tool examples corresponding with each of thecandidate transformation tools. Further, for each of the candidatetransformation tools, the computer system stores the one or more toolexamples in association with the corresponding candidate transformationtool. Based on a comparison of at least a portion of the tool exampleswith at least a portion of the set of example values, the computersystem identifies a transformation tool as relevant to facilitatetransforming the one or more example input values to the desired form inwhich to transform data.

In another aspect of the present invention, a computer-implementedmethod for facilitating data transformations is provided. A plurality ofremote sources is searched to identify a candidate transformationfunction for performing data transformations. Source code associatedwith the candidate transformation function is analyzed to identify aportion of the source code for use in generating a new transformationfunction. A new transformation function is generated and stored forsubsequent use in transforming data.

In yet another aspect, one or more computer storage media havingcomputer-executable instructions embodied thereon that, when executed byone or more processors, cause the one or more processors to perform amethod for facilitating data transformations. The method includessearching a plurality of remote sources to identify candidatetransformation tools relevant for performing data transformations. Thecandidate transformation tools are analyzed to identify one or more toolexamples corresponding with each of the candidate transformation tools.The candidate transformation tools are analyzed to identify one or moretool attributes corresponding with each of the candidate transformationtools. For each of the candidate transformation tools, the one or moretool examples and the one or more tool attributes are stored inassociation with the corresponding candidate transformation tool.

Overview of Exemplary Operating Environment

Having briefly described an overview of aspects of the technologydescribed herein, an exemplary operating environment in which aspects ofthe technology described herein may be implemented is described below inorder to provide a general context for various aspects of the technologydescribed herein.

Referring to the drawings in general, and initially to FIG. 1 inparticular, an exemplary operating environment for implementing aspectsof the technology described herein is shown and designated generally ascomputing device 100. Computing device 100 is just one example of asuitable computing environment and is not intended to suggest anylimitation as to the scope of use or functionality of the technologydescribed herein. Neither should the computing device 100 be interpretedas having any dependency or requirement relating to any one orcombination of components illustrated.

The technology described herein may be described in the general contextof computer code or machine-usable instructions, includingcomputer-executable instructions such as program components, beingexecuted by a computer or other machine, such as a personal dataassistant or other handheld device. Generally, program components,including routines, programs, objects, components, data structures, andthe like, refer to code that performs particular tasks or implementsparticular abstract data types. Aspects of the technology describedherein may be practiced in a variety of system configurations, includinghandheld devices, consumer electronics, general-purpose computers,specialty computing devices, etc. Aspects of the technology describedherein may also be practiced in distributed computing environments wheretasks are performed by remote-processing devices that are linked througha communications network.

With continued reference to FIG. 1, computing device 100 includes a bus110 that directly or indirectly couples the following devices: memory112, one or more processors 114, one or more presentation components116, input/output (I/O) ports 118, I/O components 120, an illustrativepower supply 122, and a radio(s) 124. Bus 110 represents what may be oneor more busses (such as an address bus, data bus, or combinationthereof). Although the various blocks of FIG. 1 are shown with lines forthe sake of clarity, in reality, delineating various components is notso clear, and metaphorically, the lines would more accurately be greyand fuzzy. For example, one may consider a presentation component suchas a display device to be an I/O component. Also, processors havememory. The inventors hereof recognize that such is the nature of theart, and reiterate that the diagram of FIG. 1 is merely illustrative ofan exemplary computing device that can be used in connection with one ormore aspects of the technology described herein. Distinction is not madebetween such categories as “workstation,” “server,” “laptop,” “handhelddevice,” etc., as all are contemplated within the scope of FIG. 1 andrefer to “computer” or “computing device.”

Computing device 100 typically includes a variety of computer-readablemedia. Computer-readable media can be any available media that can beaccessed by computing device 100 and includes both volatile andnonvolatile, removable and non-removable media. By way of example, andnot limitation, computer-readable media may comprise computer storagemedia and communication media. Computer storage media includes bothvolatile and nonvolatile, removable and non-removable media implementedin any method or technology for storage of information such ascomputer-readable instructions, data structures, program sub-modules, orother data.

Computer storage media includes RAM, ROM, EEPROM, flash memory or othermemory technology, CD-ROM, digital versatile disks (DVD) or otheroptical disk storage, magnetic cassettes, magnetic tape, magnetic diskstorage, or other magnetic storage devices. Computer storage media doesnot comprise a propagated data signal.

Communication media typically embodies computer-readable instructions,data structures, program sub-modules, or other data in a modulated datasignal such as a carrier wave or other transport mechanism and includesany information delivery media. The term “modulated data signal” means asignal that has one or more of its characteristics set or changed insuch a manner as to encode information in the signal. By way of example,and not limitation, communication media includes wired media such as awired network or direct-wired connection, and wireless media such asacoustic, RF, infrared, and other wireless media. Combinations of any ofthe above should also be included within the scope of computer-readablemedia.

Memory 112 includes computer storage media in the form of volatileand/or nonvolatile memory. The memory 112 may be removable,non-removable, or a combination thereof. Exemplary memory includessolid-state memory, hard drives, optical-disc drives, etc. Computingdevice 100 includes one or more processors 114 that read data fromvarious entities such as bus 110, memory 112, or I/O components 120.Presentation component(s) 116 present data indications to a user orother device. Exemplary presentation components 116 include a displaydevice, speaker, printing component, vibrating component, etc. I/Oport(s) 118 allow computing device 100 to be logically coupled to otherdevices including I/O components 120, some of which may be built in.

Illustrative I/O components include a microphone, joystick, game pad,satellite dish, scanner, printer, display device, wireless device, acontroller (such as a keyboard, and a mouse), a natural user interface(NUI) (such as touch interaction, pen (or stylus) gesture, and gazedetection), and the like. In aspects, a pen digitizer (not shown) andaccompanying input instrument (also not shown but which may include, byway of example only, a pen or a stylus) are provided in order todigitally capture freehand user input. The connection between the pendigitizer and processor(s) 114 may be direct or via a coupling utilizinga serial port, parallel port, and/or other interface and/or system busknown in the art. Furthermore, the digitizer input component may be acomponent separated from an output component such as a display device,or in some aspects, the usable input area of a digitizer may becoextensive with the display area of a display device, integrated withthe display device, or may exist as a separate device overlaying orotherwise appended to a display device. Any and all such variations, andany combination thereof, are contemplated to be within the scope ofaspects of the technology described herein.

A NUI processes air gestures, voice, or other physiological inputsgenerated by a user. Appropriate NUI inputs may be interpreted as inkstrokes for presentation in association with the computing device 100.These requests may be transmitted to the appropriate network element forfurther processing. A NUI implements any combination of speechrecognition, touch and stylus recognition, facial recognition, biometricrecognition, gesture recognition both on screen and adjacent to thescreen, air gestures, head and eye tracking, and touch recognitionassociated with displays on the computing device 100. The computingdevice 100 may be equipped with depth cameras, such as stereoscopiccamera systems, infrared camera systems, RGB camera systems, andcombinations of these, for gesture detection and recognition.Additionally, the computing device 100 may be equipped withaccelerometers or gyroscopes that enable detection of motion. The outputof the accelerometers or gyroscopes may be provided to the display ofthe computing device 100 to render immersive augmented reality orvirtual reality.

A computing device may include radio(s) 124. The radio 124 transmits andreceives radio communications. The computing device may be a wirelessterminal adapted to receive communications and media over variouswireless networks. Computing device 100 may communicate via wirelessprotocols, such as code division multiple access (“CDMA”), global systemfor mobiles (“GSM”), or time division multiple access (“TDMA”), as wellas others, to communicate with other devices. The radio communicationsmay be a short-range connection, a long-range connection, or acombination of both a short-range and a long-range wirelesstelecommunications connection. When we refer to “short” and “long” typesof connections, we do not mean to refer to the spatial relation betweentwo devices. Instead, we are generally referring to short range and longrange as different categories, or types, of connections (i.e., a primaryconnection and a secondary connection). A short-range connection mayinclude a Wi-Fi® connection to a device (e.g., mobile hotspot) thatprovides access to a wireless communications network, such as a WLANconnection using the 802.11 protocol. A Bluetooth connection to anothercomputing device is a second example of a short-range connection. Along-range connection may include a connection using one or more ofCDMA, GPRS, GSM, TDMA, and 802.16 protocols.

Overview of Exemplary Environments for Facilitating Data Transformations

Referring now to FIG. 2, a block diagram of an exemplary networkenvironment 200 suitable for use in implementing embodiments of theinvention is shown. Generally, the system 200 illustrates an environmentsuitable for transforming data that, among other things, searches fortransformation tools, generates transformation programs, and providestransformation output (e.g., transformation program suggestions and/ortransformed output values). The network environment 200 includes a userdevice 210, a transformation engine 212, a data store 214, andtransformation sources 216 a-216 n (referred to generally astransformation source(s) 216). The user device 210, the transformationengine 212, the data store 214, and the transformation sources 216 a-216n can communicate through a network 218, which may include any number ofnetworks such as, for example, a local area network (LAN), a wide areanetwork (WAN), the Internet, a cellular network, a peer-to-peer (P2P)network, a mobile network, or a combination of networks. The networkenvironment 200 shown in FIG. 2 is an example of one suitable networkenvironment and is not intended to suggest any limitation as to thescope of use or functionality of embodiments of the inventions disclosedthroughout this document. Neither should the exemplary networkenvironment 200 be interpreted as having any dependency or requirementrelated to any single component or combination of components illustratedtherein. For example, the user device 210 and transformation sources 216a-216 n may be in communication with the transformation engine 212 via amobile network or the Internet, and the transformation engine 212 may bein communication with data store 214 via a local area network. Further,although the environment 200 is illustrated with a network, one or moreof the components may directly communicate with one another, forexample, via HDMI (high-definition multimedia interface), DVI (digitalvisual interface), etc. Alternatively, one or more components may beintegrated with one another, for example, at least a portion of thetransformation engine 212 and/or data store 214 may be integrated withthe user device 210.

The user device 210 can be any kind of computing device capable offacilitating data transformations. For example, in an embodiment, theuser device 210 can be a computing device such as computing device 100,as described above with reference to FIG. 1. In embodiments, the userdevice 210 can be a personal computer (PC), a laptop computer, aworkstation, a mobile computing device, a PDA, a cell phone, or thelike.

The user device can include one or more processors, and one or morecomputer-readable media. The computer-readable media may includecomputer-readable instructions executable by the one or more processors.The instructions may be embodied by one or more applications, such asapplication 220 shown in FIG. 2. The application(s) may generally be anyapplication capable of facilitating a data transformation. In someimplementations, the application(s) comprises a web application, whichcan run in a web browser, and could be hosted at least partiallyserver-side. In addition, or instead, the application(s) can comprise adedicated application. In some cases, the application is integrated intothe operating system (e.g., as a service).

In embodiments, data transformations may be initiated and/or presentedvia an application 220 operating on the user device 210. In this regard,the user device 210, via an application 220, might allow a user toinitiate a data transformation and to obtain, in response to initiatinga data transformation, transformed output and/or transformation programsuggestions that can be used to transform data. The user device 210 caninclude any type of application that facilitates data transformations.An application may be a stand-alone application, a mobile application, aweb application, or the like. One exemplary application that may be usedfor data transformation includes a spreadsheet application. In somecases, the functionality described herein may be integrated directlywith an application or may be an add-on, or plug-in, to an application.

User device 210 can be a client device on a client-side of operatingenvironment 200, while transformation engine 212 can be on a server-sideof operating environment 200. Transformation engine 212 may compriseserver-side software designed to work in conjunction with client-sidesoftware on user device 210 so as to implement any combination of thefeatures and functionalities discussed in the present disclosure. Anexample of such client-side software is application 220 on user device210. This division of operating environment 200 is provided toillustrate one example of a suitable environment, and it is noted thereis no requirement for each implementation that any combination oftransformation engine 212 and user device 210 to remain as separateentities.

In an embodiment, the user device 210 is separate and distinct from thetransformation engine 212, the data store 214, and the transformationsources 216 illustrated in FIG. 2. In another embodiment, the userdevice 210 is integrated with one or more illustrated components. Forinstance, the user device 210 may incorporate functionality described inrelation to the transformation engine 212. For clarity of explanation,we will describe embodiments in which the user device 210, thetransformation engine 212, the data store 214, and the transformationsources 216 are separate, while understanding that this may not be thecase in various configurations contemplated within the presentinvention.

As described, data transformations change or modify data from one formto another. Data transformations may be initiated at the user device 210in any manner. For instance, upon selection of example input and/oroutput values, a “begin” or “search” function button might be selected,for example, by a user via the user interface. By way of example only, auser might select to search for a relevant data transformation programor to perform a data transformation in association with data values. Asanother example, data transformations might be automatically initiated.For instance, upon detecting an intent to perform a data transformation,a data transformation(s) can be automatically initiated to result intransformed data output, as described in more detail below.

In some cases, one or more example input values and/or example outputvalues are selected to facilitate data transformation. For instance,example input values and/or example output values can be used to searchfor appropriate transformation tools, generate a transformation program,and/or perform a data transformation. An example input value refers toan example of data desired or selected to be transformed. An exampleoutput value refers to an example of data corresponding with a form orformat to which to transform a data value. Any number of example inputvalues and/or example output values can be specified or designated. Forinstance, in some cases, each of the values desired to be transformedcan be selected, while a minimal number (e.g., 1, 2, 3) of exampleoutput values might be selected.

Example input and/or output values can be selected in any number ofways. For instance, a user might use a mouse, selector, touch input, orthe like to specify example input values and/or output values. Asanother example, example input and/or output values might beautomatically selected. By way of example only, assume a user inserts anew column adjacent to another existing column and inserts a value intothe new column. In such a case, the values in the existing column may beautomatically selected as the example input values while the valueinserted into the new column may be selected as an example output value.

Example input and/or output values can be provided as, or as part of, atransformation query to initiate a data transformation process. Forinstance, example input and/or output values might be included as atransformation query to result in one or more transformation programsuggestions that can be used to transform data. For example, uponselecting one or more example input and/or output values as well as a“begin” or “go” button or icon, the selected example input and/or outputvalues can be provided to the transformation engine 212 for use ingenerating transformation program suggestions.

The user device 210 communicates with the transformation engine 212 tofacilitate a data transformation. In embodiments, for example, a userutilizes the user device 210 to initiate a search for availabletransformation programs via the network 218. For instance, in someembodiments, the network 218 might be the Internet, and the user device210 interacts with the transformation engine 212 to obtain relevanttransformation programs, or suggestions thereof. In other embodiments,for example, the network 218 might be an enterprise network associatedwith an organization. In these embodiments, the user device 210 caninteract with the transformation engine 212 to search for transformationprograms stored on or composed from various nodes within the enterprisenetwork. It should be apparent to those having skill in the relevantarts that any number of other implementation scenarios may be possibleas well.

With continued reference to FIG. 2, the transformation engine 212generally provides data transformation services. Generally, thetransformation engine 212 searches for transformation tools relevant toa desired data transformation and uses such tools to generate atransformation program(s) to perform the desired data transformation.The transformation program(s) can be provided as a transformationprogram suggestion(s) to the user device 210 and/or used to generatetransformed output values. The transformation engine 212, according toembodiments, can be implemented as server systems, program modules,virtual machines, components of a server or servers, networks, and thelike.

As described, the transformation engine 212 may perform a search for atransformation tool(s) to utilize for data transformation. As such, thetransformation engine 212 may be or include, for example, a searchengine, a crawler, or the like. A search for a relevant transformationtool(s) can be triggered based on a transformation query submitted viathe user device 210, or another component.

In embodiments, the transformation engine 212 receives transformationqueries initiated via the user device 210. Transformation queriesreceived from a user device, such as user device 210, can includetransformation queries that were manually or explicitly input by theuser (input queries) as well as transformation queries that wereautomatically generated. By way of example, a transformation query mightbe specified by a user based on the user selecting an example inputvalue(s) and/or an example output value(s), selecting a “transformation”button, and/or the like. Transformation queries can additionally oralternatively be automatically generated and received at thetransformation engine 212. For instance, upon creating a new column andinserting a data value, a transformation query might be automaticallytriggered. As another example, a background process might detect ascenario in which a consistent format might be desired and, thereafter,automatically initiate a transformation query to either providetransformation program suggestions, or transformed output suggestions.For instance, upon recognizing heterogeneous formats used within acolumn of data, a transformation might be automatically initiated toprovide a transformation program suggestion that can transform the datato a consistent format, or provide transformed output suggestions tostandardize the data format. Generally, the transformation engine 212can receive transformation queries from any number of devices.

In accordance with receiving a transformation query (e.g., via the userdevice 210), the transformation engine 212 can perform a search forrelevant transformation tools. As described, a transformation toolrefers to any type of tool that can be used to facilitate a datatransformation. In this way, a transformation tool can be used toconvert or transform data from one format to another. A transformationtool can be a transformation function, a transformation table, atransformation service, a transformation operator, or a combinationthereof. A transformation function refers to any function, source code,or code structure that can be used to transform data from one form toanother. In embodiments, a transformation function may perform asemantic transformation, a syntactic transformation, or a combinationthereof. A transformation table refers to any table that provides anoriginal set of data and a transformed set of data. A transformationservice refers to a service, such as a web service, that is used toperform a data transformation. For example, an exemplary web service isBING® Maps (a service available from Microsoft Corporation of Redmond,Wash.), for which an address string can be provided and a structured,segmented field(s) for that address can be provided in return. Atransformation operator refers to an operator that can be used toperform a syntactic transformation. For instance, a transformationoperator may be in the form of a concatenation operator, a splitoperator, a numeric operator (e.g., number formatting, rounding,scientific notation, linear transformation, unit conversion), or thelike.

As described in more detail below, to obtain transformation tools fromwhich to search for use in performing a data transformation, thetransformation engine 212 can identify and collect transformation toolsfrom various sources, such as transformation sources 216 a-216 n. Inthis regard, the transformation engine 212 can crawl various sources toidentify candidate transformation tools that can be used in performing adata transformation. The identified transformation tools can be stored,for example, in the data store 214. Further, to effectively search forrelevant transformation tools, the transformation engine 212 mightannotate the transformation tools. In this manner, collectedtransformation tools can be analyzed to identify annotations for use insearching and/or ranking the transformation tools. Various annotationsassociated with the performance and use of transformation tools can begenerated. For example, annotations for a transformation function mayinclude calling examples, that is, examples of values or strings inputto and/or output from the particular transformation function.

In accordance with receiving a transformation query (e.g., from userdevice 210), the transformation engine 212 can search for relevanttransformation tools using the corresponding tool annotations. By way ofexample only, relevant transformation functions might be identified andranked based on example input values and/or example output valuescompared to calling input and/or output examples associated withtransformation functions. Additional or alternative analysis might beapplied to identify and/or rank relevant transformation tools, some ofwhich are described in more detail herein.

The transformation engine 212 can use a relevant transformation tool(s)to obtain or generate a transformation program. A transformation programrefers to any computer program that can be used to perform a datatransformation. In some cases, a transformation tool deemed relevant canbe used as a transformation program to perform a data transformation.For example, in the event a transformation tool operates to perform adesired transformation, the transformation tool (e.g., a function) maybe provided as a transformation program suggestion. In other cases, atransformation tool deemed relevant can be used to generate atransformation program that achieves a desired data transformation. Byway of example, in some cases, a transformation tool, such as anexisting transformation function, may generally be relevant to a desireddata transformation, but not result in the desired data transformation(e.g., as indicated by example output values provided by a user). Assuch, an additional or supplemental transformation tool might beavailable or generated to achieve a desired data transformation. Forinstance, a transformation operator that can apply a syntactical datatransformation may be identified and applied in conjunction with thetransformation tool to achieve a desired data transformation.

Upon identifying or generating transformation programs that satisfy orare relevant to the transformation query, the transformation engine 212can return a set of one or more transformation output, such astransformation program suggestions and/or transformed output values, tothe user device 210. Transformation output generally refers to outputassociated with a data transformation. A transformation programsuggestion refers to a suggestion of a transformation program that canbe used to transform data. Such transformation program suggestions maybe displayed by way of a graphical interface. A user may select atransformation program suggestion to view data transformation results,or a preview thereof.

A transformed output value refers to an output value resulting fromapplication of a transformation program to transform data. Suchtransformed output values may be displayed by way of a graphical userinterface. Transformed output values might be provided in response to auser input (e.g., selection of a transformation program suggestion) orautomatically. For instance, a transformation program may beautomatically used to perform a data transformation in accordance withreceiving a transformation query and generating a transformation programto apply to selected example input values. A transformation programgenerated for the specific data values can be automatically applied togenerate desired output values.

By way of example only, and with reference to FIG. 3, FIG. 3 illustratesan example user interface 300 associated with a data transformation. Asillustrated, column A 310 represents various formats of dates on whichparticular transactions occurred. To perform a data transformation inaccordance with embodiments of the present invention, assume a usercreates a new column B 312 adjacent to the various date formats. Furtherassume that the user enters or inputs two sample outputs in a desiredformat, example output value 314 and example output value 316. Uponselecting the “go” button 318, various collected transformation tools,such as functions and tables, can be searched to identify relevanttransformation tools. Relevant transformation tools can be identified,for instance, using example input values of column A 310 and exampleoutput values 314 and 316. As can be appreciated, the output generatedby a particular transformation tool, such as a transformation function,may not match the example output value(s) provided by a user (e.g.,example output values 314 and 316). As such, a relevant transformationtool can be used as an underlying tool (e.g., function) to dynamicallycompose a transformation program that produces transformed output valuesmatching the example output value 314 and the example output value 316.As shown, two composed transformation programs 320 and 322 are providedas suggestions. Such transformation program 320 and 322 can berepresented in any manner, such as via an indication of the underlyingtransformation tool used to generate the transformation program.

Now assume the user selects, or hovers over, a particular transformationprogram suggestion, such as transformation program suggestion 320. Insuch a case, transformed output values 324, or preview thereof, can beprovided corresponding with the remaining input values. In some cases,the source code of the composed transformation program is available, orcan be provided, to a user such that the user can review and/or modifythe source code. For example, a user may select a transformation programsuggestion, such as transformation program 320, to view the source code.This is only one example of potential user interface aspects ofembodiments of the present invention and is not intended to limit thescope of the invention. Other examples are provided herein, for example,with reference to FIGS. 7-9.

Turning now to FIG. 4, FIG. 4 illustrates an example transformationengine 412. In embodiments, the transformation engine 412 includes atool collector 420, a tool annotator 422, a data indexer 424, and a datatransformer 426. According to embodiments of the invention, thetransformation engine 412 can include any number of other components notillustrated. In some embodiments, one or more of the illustratedcomponents 420, 422, 424, and 426 can be integrated into a singlecomponent or can be divided into a number of different components.Components 420, 422, 424, and 426 can be implemented on any number ofmachines and can be integrated, as desired, with any number of otherfunctionalities or services.

The transformation engine 412 can communicate with the data repository430. The data repository 430 is configured to store various types ofinformation used by the transformation engine 412. In embodiments, thetransformation engine 412 provides transformation data to the datarepository 430 for storage, which may be retrieved or referenced by thetransformation engine 412. Examples of types of information stored indata repository 430 may include, for example, example input values,example output values, transformation functions, transformation tables,transformation services, transformation operators, transformation toolsources (e.g., source code), transformation tool references, toolexamples, calling input examples, calling output examples,transformation tool annotations, tool attributes (e.g., toolrelationships, tool popularity, tool usage, tool author, tooldifficulty, etc.), indexes, or the like.

The tool collector 420 is generally configured to collect transformationtools, or references thereto. As described herein, a transformation toolmight be a transformation function, a transformation table, atransformation service, a transformation operator, or the like. Inembodiments, the tool collector 420 collects existing transformationtools from one or more sources, such as sources 216 a-216 n in FIG. 2.Transformation tools can be collected from various types of sources. Forexample, transformation tools can be collected from code libraries(e.g., GitHub and Stack Overflow), web sources (e.g., web pages havingcode or mapping tables, such as Wikipedia.com), web service calls (e.g.,via REST APIs), electronic spreadsheets (e.g., functions and mappingtables), electronic documents, or the like. As can be appreciated,collected transformation tools, such as functions, can be in anylanguage and are not required to be in a domain specific language.

To collect existing transformation tools, embodiments of the inventionenable the tool collector 420 to crawl code and content from varioussources, for example, on the web. To this end, the tool collector 420can crawl web pages, electronic documents, etc. searching for functions,mapping tables, or other structured data that can be designated as atransformation tool.

To search for existing mapping tables, any type of sources can becrawled to identify mapping tables. For examples, web pages might becrawled to identify existing mapping tables, or other structured data.As another example, electronic documents and spreadsheets might becrawled and analyzed to identify mapping tables, or other structureddata. As can be appreciated, in some embodiments, mapping tables can begenerated and collected. For instance, data can be provided to a webservice to obtain corresponding transformed output, which can then beused to generate a mapping table. Other methods can be employed togenerate mapping tables, and implementations are not intended to belimited hereto.

To search for existing transformation functions, source code can becrawled to identify transformation functions. In particular, source codecan be analyzed to identify any functions that take a string into anargument and then perform an operation in connection with that string(i.e., functions that take strings and return strings). The source codecan be compiled to result in compiled or executable code that canadditionally or alternatively be collected. In one embodiment, thesource code can be compiled using a makefile. In some cases, source codemay be identified that is in a non-compatible state. A non-compatiblestate refers to a state in which the source code cannot currently becompiled. For example, a snippet of code may be identified, forinstance, in association with a website (e.g., Stack Overflow) at whicha user may provide a code snippet as a solution to another user'squestion. In such a case, the code snippet might define the function,but not include dependencies of the function (e.g., assuming that theuser posting the question understands what to do with the code snippet).In such cases, the tool collector 420 can analyze the code snippet todetermine how to generate compilable code, that is, code that can becompiled. For example, one or more dependencies of a function may bedetermined, a language in which the function is written may beidentified, etc. such that a code snippet can be converted to compilablecode.

As another example, to search for existing transformation functions, adynamic-link library (DLL) file can be crawled to identifytransformation functions exposed by such a library. Other examples ofmethods for collecting transformation tools includes analyzing and/orcollecting binary code, performing reverse compilation related todetermining function calls in a library, etc.

In addition to searching for existing transformation tools, the toolcollector 420 can be configured to generate or author new transformationtools, such as transformation functions. For example, a transformationfunction that takes a string and outputs a string can be generated fromexisting program code. Generating new transformation tools can occur inany number of manners. In one implementation, identified or collectedsource code can be used to generate new transformation functions. Inparticular, source code identified via a search (e.g., web search) canbe analyzed to identify new functions. By way of example only, andwithout limitation, assume that a function (e.g., identified within testcode) without any initial parameters or arguments, but with one or moreconstants, is identified. In such a case, a constant(s) (e.g., hardcoded constant string) can be identified and used as a parameter orvariable to the function to generate a new function. In this regard, afunction that did not originally take arguments or parameters can begenerated into a transformation function by transforming a constantcorresponding with the function into a variable to take as input suchthat the new transformation function takes an argument or parameterincluding the constant. Although a constant within an original functionis generally described herein as being used as input for generating anew transformation function, as can be appreciated, another parametercould also be used. Additional examples of generating new transformationfunctions include modifying existing source code to generate newfunctions by, for example, taking a sub-segment of code from an existingfunction, or changing the number of parameters in a function, etc.

To identify source code from which new transformation functions can bemade, the tool collector 420 may search for source code having afunction(s) that does not take an argument but internally has a constantstring. In some instances, to identify a constant for use as a parameteror variable, some setting up and/or calling another function may occur.For instance, a given function called can be analyzed to identifydependencies within the existing source code and to identify a subset ofthe code for use in generating other requirements of that function call.By way of example only, test code might exist that internally has aconstant (e.g., x equals a constant phone number string), and the testcode may call another function with that constant.

In some implementations, the source code is analyzed to identifycombination of functions or locations at which to split functions inorder to generate a new transformation function. For example, in somecases, a first function might be called, followed by calling a secondfunction and then a third function to arrive at a desired output. Insuch a case, a sequence of the three functions can be identified andcombined to generate a new transformation function. As another example,only a portion of an existing function may be identified as a newtransformation function. In this case, the tool collector 420 cananalyze where to split the function for use as the new function.

Upon identifying and collecting transformation tools, or referencesthereto, the tool collector 420 can store the collected tools orreferences in a data repository 430. A reference to a transformationtool provides an indication or pointer as to where to obtain thetransformation tool. For example, in the case that a transformation toolis a web service, a reference providing an indication or link to the webservice may be collected and stored in a repository. As another example,in the case the transformation tool is a mapping table or function, areference providing an indication or link to the mapping table orfunction (e.g., via a URL) may be collected and stored in therepository. Alternatively or additionally to collecting and storingtransformation tools, the tool collector 420 can store aspects of thesource. For example, source code from which a transformation function isidentified might be stored.

Although web searching has generally been described for identifyingtransformation tools, in accordance with some implementations, one ormore enterprise searches may additionally or alternatively be employedto obtain transformation tools. An enterprise search refers to a searchof a source(s) owned and/or operated by an organization. In embodiments,an enterprise search enables a search for transformation tools thatinclude data unique to that enterprise. For instance, an enterprisesearch can result in various domain specific semantic functions thattransform data generally associated with the enterprise. By way ofexample only, an enterprise search may include crawling electronicspreadsheets, electronic documents, databases, lookup tables, sourcecode repository(s) having various functions, unique dynamic linklibraries (DLLs), web services, etc. relevant to the enterprise.Performing enterprise searches can be beneficial as different industriesand application domains often have domain-specific problems andproprietary data sets.

In accordance with receiving or identifying enterprise sources tosearch, transformation tools can be identified, extracted, and/orcollected by the tool collector 420. In some cases, such transformationtools, or references thereto, might be stored among other externalsources in data repository 430. In other cases, enterprisetransformation tools may be stored remote and distinct from the otherexternal sources. Enterprise transformation tools might generally bereferred to here as transformation tools.

As will be described in more detail below, utilization of suchenterprise transformation tools may vary in different embodiments, forexample, depending on security levels associated with the enterprisetransformation tools. For example, in some cases, enterprisetransformation tools might be available for use in providingtransformation program suggestions and/or transformed output values forthe user(s) that provided the tool, for any users within the enterprise,for users within the domain or industry, for any user, etc.

In some embodiments, users may provide transformation tools or sourcesthat are accessible to the tool collector 420 to search fortransformation tools. In this regard, a user may upload or otherwiseprovide a transformation tool, or source code, mapping tables, or thelike for use in searching for transformation tools. For instance, a usermay upload source code utilized to perform a particular datatransformation. In some cases, the user may also provide detailspertaining to the transformation tool or source, such as the originatorof the source, the type of data transformation performed, etc. Suchtransformation tools, or sources, can be stored, for example, in thedata repository 430. User provided transformation tools might beavailable to users dependent on security levels associated with theprovided tools.

FIG. 5 illustrates an exemplary user interface enabling a user to inputone or more transformation tools, or sources, that can be accessed tosubsequently search for transformation tools related to a particulartransformation query. In particular, a user may select tools 502 and bepresented with various types of transformation tools that may be addedto a data repository. As shown, a user may select to add a user-definedfunction 504, a custom DLL 506, a service 508, or a table 510. Assumethe user selects to add a custom DLL 506. In such a case, the user canbe presented with the user interface 512 that enables the user to browseand select a custom DLL to be added as a new transformation tool, orsource from which to search for transformation tools.

The tool annotator 422 generally generates or provides annotations fortransformation tools. Annotating transformation tools enables the toolsto be more efficiently identified and/or ranked for use in performingsubsequent data transformations. To annotate transformation tools, thetool annotator 422 generally analyzes the transformation tool, and/orthe source associated therewith, to identify characteristics associatedwith the transformation tool. Annotations can include any type of dataor metadata characterizing, describing, or associated with thetransformation tool, or source associated therewith. By way of example,annotations can include tool attributes or tool examples (e.g., inputcalling examples and/or output calling examples).

Tool examples refer to examples of input and/or output data associatedwith a transformation tool. In this regard, a tool input example refersgenerally to an example data that could be or has been transformed by atransformation tool. A tool output example refers generally to anexample data that could or has resulted from a transformation performedby a transformation tool. Tool examples can correspond with any type oftransformation tool, such as transformation functions, transformationtables, transformation services, and transformation operators, asdescribed herein. Tool examples can be calling examples, table examples,service examples, and operator examples. Calling examples refer examplesof actual or proposed usage of a transformation function. In this way,calling examples facilitate an understanding of input values passed intoa function as a parameter(s) and output values returned from thefunction. Input calling examples generally refer to values input to afunction, while output calling examples generally refer to valuesreturned from the function. Table examples refer to examples of actualor proposed entries or values in a table. Service examples refer toexamples of actual or proposed values for input to and output from atransformation service. Operator examples refer to examples of actual orproposed values for input to and output from an operation.

Tool examples can be identified in any number of ways, some of which aredescribed herein. For instance, calling examples can be identified usingstatic analysis, dynamic analysis, user logging, or the like. In somecases, analyzing source code to identify calling examples may occur viastatic analysis. Static analysis might be performed, for instance, incases that the source code being analyzed is test code. With staticanalysis, the source code can be inspected and parsed. For example, acompiler tool(s) can be used to inspect and parse the source code intoan abstract syntax tree of various fields, such as functions, constants,etc. In accordance with the static analysis, constants being passed intoa function can be identified and designated as input calling examples.For instance, assume that a function includes a constant that is in theform of a phone number. In such a case, a phone number can be identifiedas an input calling example.

By way of example only, assume a function exists that can parse data andoutput a date/time object. Further assume that source code associatedwith the function is analyzed to identify calling examples. Forinstance, test code that shows how to use the function or some samplecode provided as a proper usage of the function might be identified inconnection with the function and statically analyzed to identify callingexamples. In such a case, a compiling tool(s) can be used to inspect thesource code and generate an abstract syntax tree, parsing the sourcecode into various code aspects, such as constants. Upon identifying aconstant that is a string passed into the function, it can be recognizedthat a date/time string is being called by the date/time parse function.Accordingly, the date/time string can be identified as an input callingexample.

Additionally or alternatively, in some cases, analyzing source code toidentify calling examples may occur via dynamic analysis. With dynamicanalysis, source code, or a portion thereof (e.g., transformationfunction), may be modified or injected with logging code that can beused to log arguments being passed into a transformation function. Assuch, when a program is being executed and uses a particulartransformation function, an argument going into the function can beidentified and designated as an input calling example. Further, thelogging code can also be used to obtain output calling examples beinggenerated from execution of the function.

Another implementation for obtaining calling examples includesutilization of user logging via the transformation engine. In thisregard, as a user provides example input values and/or example outputvalues and, thereafter, utilizes a transformation program to generatetransformed data output, the input and/or output example values can belogged as calling examples for a function employed in association withthe transformation program. In some cases, utilization of atransformation program to generate transformed output values mightresult in annotating a transformation function (used by thetransformation program) with the data input to the transformationprogram and the transformed output values produced by the transformationprogram as calling examples. In embodiments, a user may confirm orverify transformed output values prior to the annotation or recordationof a transformation function with calling examples.

Input and/or output calling examples can be recorded as annotations inany manner. For instance, in some cases, a repository or data store canbe used to store the recorded annotations. In some cases, as can beappreciated, calling examples can be aggregated for a function. In thisregard, calling examples obtained in any manner can be aggregated, orstored collectively, when such calling examples are associated with aparticular transformation function. Accordingly, calling examplesobtained by a static analysis, dynamic analysis, and/or user logginganalysis can be collected and aggregated in association with acorresponding transformation function. Aggregating calling examplesenables a larger set of calling examples for a transformation functionthereby resulting in a more robust manner to utilize the transformationfunction.

By way of example only, assume that a first test code calls a date/timefunction, and a second test code also calls the same date/time function.The date/time function included in the first test code can be analyzedseparate from the date/time function included in the second test code.The calling examples identified via analysis of the first test code canbe combined with the calling examples identified via analysis of thesecond test code. As can be appreciated, this example can beextrapolated out such that any number of instances of a function can beanalyzed. For instance, each instance or place from which a function iscalled can be analyzed to aggregate all the calling examples associatedtherewith.

Recognizing various usage of a transformation function to obtain relatedcalling examples can be performed in any manner. As one example, uponidentifying a transformation function in one source, other sources canthen be crawled or searched to identify such a transformation functionwithin those sources. Analyzing a transformation function withinmultiple sources enables more raw data to be gathered in associationwith that function. Further, analyzing transformation functionsassociated with various sources can be performed over multipleprogramming languages. In some cases, to the extent diverse programminglanguages are used in association with a transformation function,annotations can be generated in a common format.

In some implementations, calling examples for a particulartransformation function may be extended. To this end, a transformationfunction having a limited number of calling examples can be associatedwith a greater number of calling examples. Extending a number of callingexamples for a particular transformation function can occur using otheridentified functions that may be similar. In one implementation, toidentify a similar transformation function, a comparison of input and/oroutput calling examples can be compared between transformationfunctions. For instance, an analysis of one function may tend to have aset of calling examples of a first pattern, which is similar to patternof calling examples associated with another function. In this way,functions may be deemed similar if a pattern derived from one functionwould work the same or similar if implemented in the other function. Tothe extent that functions are deemed similar, calling examplesassociated with both functions can be aggregated to extend the set ofcalling examples.

Another implementation for extending calling examples includesutilization of tables, such as web tables. By way of example only,assume a particular transformation function corresponds with only athree dates as input calling examples. Further assume that a web tableis identified that has 1,000 dates listed in one of the columnsincluding the three dates corresponding with the transformationfunction. In such a case, each of the additional dates in the web tablecan be used as calling examples for the transformation function, such asinput calling examples for the transformation function.

Other transformation tools can also be annotated with tool examples. Forexample, a table can be annotated based on table examples. That is, datato be transformed and data that has been transformed can be captured andused as annotations for a table. As another example, a transformationservice can be annotated based on service examples, such as data inputinto a transformation service and data output from a transformationservice. For an operator, the data to be transformed and the data thathas been transformed can be captured and used as annotations for anoperator tool.

In addition or alternatively to annotating a transformation tool withtool examples, tool attributes annotations can be identified orgenerated. Tool attributes generally refer to any data or metadataassociated with a transformation tool, or source associated therewith.As will be described in more detail below, tool attributes can be usedto identify and/or rank transformation tools relevant to particular setof example values (example input and/or output values).

Various types of tool attributes include, for example, tool popularity(e.g., page rank), tool usage (e.g., hits or clicks), tool author, toolcomplexity, tool relationships, calling patterns, or the like.Identifying tool attributes and/or a particular set of tool attributesto identify may vary depending on a source or type of transformationtool. For example, assume a transformation tool is provided via WebsiteA. In such a case, Website A might be analyzed to identify toolattributes such as tool popularity (e.g., because Website A is popularin terms of page rank of the Website, tool popularity might be rankedhigh). Further, visitors obtained via the website or the author of thefunction can be identified as tool attributes for the transformationtool. As another example, tool popularity might be high if a particulartransformation tool, such as a mapping table, frequently appears on theweb, appears on more than a threshold number of web sites, or isaccessed more frequently. As another example, in an enterpriseenvironment, tool popularity might be based on a number of employeesthat call a function, access a mapping table, etc.; or a number ofelectronic documents (e.g., spreadsheets) that call a function, etc. Asyet another example, tools such as tables can be compared across the webto identify various attributes, such as what fraction of records arecorrect, does a particular table agree with most of the other tablesthat are similar, does a function agree with other functions that haresimilar inputs and outputs, or the like.

A tool relationship attribute refers to data corresponding with arelationship or association between transformation tools. In thisregard, a transformation tool can be identified as related to anothertransformation tool. For example, transformation tool A can beidentified as related to transformation tool B when transformation toolA is called by transformation tool B, or transformation tool A is usedto generate parameters to call transformation tool B. In addition to anindication of a relationship between transformation tools, further toolrelationship attributes can be identified, for instance, based onfrequency at which a transformation tool is called by another. As can beappreciated, relationships between functions can be learned, such as, isone function an inverse of another function (e.g., determine that callfunction 1 with a target and use the provided path expression to callfunction 2 to identify if the target is provided in response), or aretwo functions algebraically related.

Another tool attribute may be a tool pattern. A tool pattern refers to apattern generalized from analysis of one or more tool examples, such asinput and/or output calling examples. In this regard, a tool patterngeneralizes or summarizes one or more tool examples as a pattern. Toolpatterns can be represented in any manner, for instance, using numerals,alphabet characters, symbols, formats, etc. As will be described in moredetail below, tool patterns can be used in some implementations toassociate example values with the annotated data.

The data indexer 424 can use annotations, or other data, to generateindexes. Upon identifying annotations for transformation tools, suchannotations can be used to generate one or more indexes. Generally, thegenerated data indexes can be used at run-time to search for and/or rankrelevant transformation tools or programs. The data indexer 424 mightgenerate indexes in an offline manner or in an online manner, inaccordance with various implementations of the present invention.

As can be appreciated, any type of index or number of indexes might begenerated. Embodiments described herein contemplate forward indexes,inverted indexes, etc. Further, any type of content may be included orreferenced in an index. One example of a data index might be anexample-tool index (e.g., a keyword index using tool examples, orportions thereof, as keyword tokens). In this regard, the data index canreference or associate transformation tools, such as functions, withtool examples, such as input and/or output calling examples. Forinstance, a function might be associated with calling examples thatrepresent state names and abbreviations such that an example input valuebeing a state name or abbreviation can utilize the index to search foror identify transformation functions that have the same token of statename or abbreviation.

Another example of a data index might be a pattern-tool index. In thisexample, the data index can reference or associate transformation tools,such as functions, with one or more tool patterns. As previouslydescribed, a tool pattern reflects or represents a pattern of one ormore tool examples, such as input calling examples. Such tool patternscan be patterns generated by analysis of the calling examples that areaccepted by each function, table examples included in a table, etc.

In generating indexes, in some embodiments, the data indexer 424 cancompress data such that the indexes can operate more efficiently. Inthis manner, the data indexer 424 can identify and remove redundancy,such as redundant tool examples. For instance, with reference to anexample-tool index, redundant calling examples can be identified andremoved from an index, or not used in generating an index. In additionto or in the alternative to discarding duplicative tool examples, a toolexample(s) can be removed based on an association to a duplicativepattern associated therewith. By way of example only, assume that twotool examples correspond with a same syntactic pattern. In such a case,one of the tool examples with that syntactic pattern can be removed. Tothis end, tool examples with a same or similar syntactic pattern can beconsidered redundant from a pattern distance perspective (or syntacticdistance). For instance, calling examples that maintain distance topatterns that have been extracted from the calling examples can bereduced.

As another example, with reference to a pattern-tool index, redundant orduplicative patterns can be discarded from an index, or not used ingenerating an index. As described, such patterns might generalize toolsamples associated with a transformation tool. By removing a duplicativepattern, the index is compressed. For instance, assume two input callingexamples correspond with a same syntactic pattern. In such a case, oneof the patterns can be discarded.

The data transformer 426 is generally configured to facilitate datatransformation. At a high level, the data transformer 426 can facilitatedata transformation by identifying and/or ranking transformation toolsrelevant to example input and/or output values, identifying and/orranking transformation programs for use in performing datatransformation, and the like.

The data transformer 426 can receive a set of example values. The set ofexample values generally include one or more example input values andone or more example output values. As previously described, the examplevalues set can be selected or designated in any manner, for example, viaa user device. Any number of example values can be received. In oneembodiment, a minimal number of example output values might be received,such as, for instance, one example output value. As can be appreciated,an example output value is not needed for each example input value.

Based on the example input and/or output values, the data transformer426 can search for one or more transformation tools (e.g., via a libraryor repository including a vast number of tools) that can be used totransform data that aligns, matches, or corresponds with the providedexample output value(s). As such, the collected transformation tools,such as functions and/or tables, can be searched to identify any numberof tools relevant to the desired data transformation.

In some cases, an identified transformation tool may be in form toperform the desired data transformation. For example, a function mightexist that can take input and provide the desired output. In such cases,the transformation tool can be identified and provided as atransformation program that can perform the desired data transformation.In other cases, an identified transformation tool may facilitate a datatransformation, but additional assistance may be needed to perform thedesired data transformation. In such cases, a supplementaltransformation tool can be identified or developed and used inassociation with the identified transformation tool to generate atransformation program that can perform the desired data transformation.As can be appreciated, and as described in more detail below withrespect to FIG. 6, identified transformation tools and/or transformationprograms can be ranked (e.g., based on a variety of features) such thattools and/or programs more relevant to a desired data transformation canbe provided or utilized to transform data.

Upon obtaining one or more transformation programs that can be used toperform a desired data transformation, the relevant transformationprogram(s) can be provided as a suggestion and/or for use in performingthe data transformation. In this regard, a user may select atransformation program suggestion to effectuate the desired datatransformation, or preview the desired data transformation. In othercases, upon identifying a transformation program that can be used toperform a desired data transformation, such a transformation program maybe automatically initiated to perform the data transformation. By way ofexample only, a desired data transformation might be automaticallyapplied upon a user selecting a set of example values resulting intransformed output values being provided.

FIG. 6 provides an example of a data transformer environment 600 thatcan be used to facilitate data transformations. As shown in FIG. 6, thedata transformer 626 in FIG. 6 includes an example receiver 602, atransformation tool identifier 604, a transformation program generator606, a transformation program ranker 608, and a transformation provider610. According to embodiments of the invention, the data transformer 626can include any number of other components not illustrated. In someembodiments, one or more of the illustrated components 602, 604, 606,608, and 610 can be integrated into a single component or can be dividedinto a number of different components. Components 602, 604, 606, 608,and 610 can be implemented on any number of machines and can beintegrated, as desired, with any number of other functionalities orservices.

As shown, a transformation query 630 can be provided as input to thedata transformer 626. The transformation query 630 might be receivedfrom a user device at which a data transformation is initiated.Generally, the transformation query 630 initiates a data transformation,or services associated therewith (e.g., obtaining program suggestions,etc.). To facilitate a data transformation or corresponding service,such as generation of a transformation program, the transformation query630 can include example input value(s) 632 and example output value(s)634. Such example values can be used by the data transformer 626 tounderstand a desired data transformation.

The example receiver 602 is configured to receive example values. A setof examples values generally include one or more example input valuesand one or more example output values. As shown, the example values,such as example input values 632 and example output values 634, can bereceived in association with a transformation query. As previouslydescribed, a set of example values can be selected or designated in anymanner, for example, via a user device. For instance, a set of examplevalues can be explicitly selected by a user or automatically selected.Any number of example values can be received. In one embodiment, aminimal number of example output values might be received, such as, forinstance, one example output value. As can be appreciated, an exampleoutput value is not required for each example input value received.

Based on the example input and/or output values, the transformation toolidentifier 604 generally identifies one or more transformation toolsrelevant to the set of example values. To identify one or moretransformation tools relevant to the set of example values, generatedannotations and/or indexes can be used. For instance, using examplevalues and a function index, at runtime, an analysis can be performed toidentify a smaller set of functions likely to be relevant. Variousmethods can be employed to search for and identify transformation toolsrelevant to a desired data transformation. Further, as can beappreciated, any type of transformation tool may be searched toinitially identify relevant transformation tools.

In one implementation, to identify a relevant transformation tool(s) foruse in performing a data transformation, a set of example input valuescan be compared to various input tool examples. In this regard, atransformation function (or other tool) can be identified as relevantwhen one or more example input values match or correspond with an inputcalling example associated with that transformation function. That is,transformation functions that have inputs the same or similar to exampleinput values can be identified. Such transformation tools can beidentified using annotations and/or a data index(s). As can beappreciated, in searching for relevant transformation tools, the exampleinput values can be parsed into tokens. For instance, delimiters mightbe used to parse the example input values. Upon parsing the exampleinput values, the parsed tokens can be used to search for relevantfunctions based on a particular parsed token matching or correspondingwith a tool input example, or portion thereof. By way of example only,assume an example input value is in the form of “September 2016.” Insuch a case, the example input value can be parsed into “September” and“2016,” with each token compared against input calling examples todetermine which functions have input calling examples most similar tothe “September” token and/or “2016” token. In some cases, the set oftokens for an example input value can be used to identify a functionthat has a greatest overlap in association with the calling examples.

In an alternative or additional implementation, a set of example values,such as example input and/or output values, might be compared to varioustool patterns to identify relevant transformation tools (e.g.,functions). In such a case, the example values can be compared to thetool example patterns. Alternatively, the example values can beconverted to an example pattern, that is, a pattern of the examplevalues, and thereafter compared to tool patterns.

Another approach for identifying relevant transformation tools includesperforming a nearest-neighbor search that searches for tool examplesmost similar, or nearest, to one or more example values, such as exampleinput values. By way of example only, assume that an example input valueis received. In such a case, the example input value(s) can be comparedto each calling input example to find calling input examples that aresimilar (e.g., exceed a similarity threshold) to the example inputvalue(s). Such a nearest neighbor approach can be used to compare thevalues or patterns associated therewith.

Yet another approach to identify relevant transformation tools uses ahierarchical structure. In such an implementation, calling examples canbe analyzed and formed into a hierarchical structure. A hierarchicalstructure can be in any form. As one example, a hierarchical structuremay characterize data based on value type. For instance, numbers mightbe one data category, while alphabet characters might be another datacategory or level in the hierarchy. In response to receiving examplevalues, such as example input values, the hierarchical tree of callingexamples for a particular function can be traversed to identifyfunctions that are relevant to the received example values.

Another hierarchical structure for identifying relevant transformationtools includes a tree-structure used to represent the input/outputrelationship for a transformation tool, such as a function. In thisregard, a transformation tool is described as the difference between itscalling input/output pairs using a tree representation. Upon receivingexample values, the example input values and example output values canbe described in a similar tree representation and compared with the treestructures representing the transformation tools. By way of exampleonly, assume that a transformation function performs camel-casing (i.e.,writes compound words or phrases such that each word or abbreviation inthe middle of the phrase begins with a capital letter). In a treestructure, the transformation function can be described as onlymodifying casing. Now assume that the example input and output valuesalso differ only by casing, as characterized by the tree structure.Accordingly, the transformation function can be identified as relevantto the desired data transformation based on the similarity in the treestructures. This approach can be particularly useful when thetransformation tools, such as transformation functions, performsyntactic transformations.

Syntactic distance can also be used to identify relevant transformationtools. Syntactic distance refers to a distance or other indication ofextent of syntactical difference. In this approach, syntactic distancecan be used to compare values of example values and tool examples, orpatterns associated therewith. For example, a pattern can be generatedfrom example input values and a pattern can be generated for callinginput examples. The two patterns can then be compared to identify asyntactic distance. Syntactic distance can be determined in any numberof manners. As one example, a syntactic distance between a numericalvalue in one pattern and a numerical value in another pattern might berepresented by a 0. Similarly, a syntactic distance between analphabetical value in one pattern and an alphabetical value in anotherpattern might also be represented by a 0. While the values may bedifferent, such a syntactic distance may be “0” to indicate lack of asyntactical difference. By comparison, a numerical value in one patterncompared to an alphabetical value in another pattern might result in asyntactic difference of 0.5. In this regard, types of data might becompared to one another (e.g., numerical, textual, symbolical,delimiter, length of data, format of data, etc.). As such, in accordancewith embodiments of the present invention, portions of each of thepatterns can be compared to one another to determine syntactic distance.For instance, a first portion before a delimiter of one pattern can becompared to a first portion before a delimit of another pattern.Further, delimiters can be compared to one another. The syntacticaldifferences might be aggregated to result in an aggregated syntacticaldifference between the patterns. Although syntactical distance isdescribed in relation to patterns, as can be appreciated, a syntacticaldistance can similarly be determined based on the original values.Further syntactical distance can be used in association with an aboveapproach (e.g., a hierarchical structure) to identify a relevant tool.

As can be appreciated, in association with identifying relevanttransformation tools, the transformation tools can be ranked based onthe analysis. In this regard, tool rankings can be generated based on,for example, an extent of similarity or degree of overlap between anexample value(s) and a tool example(s). For example, given a set oftokens associated with example values, transformation functions can beranked based on an amount of overlap with calling examples. In somecases, a tool ranking might occur using a single tool identificationmethod described above, while in other cases, a tool ranking might occurbased on a combination of tool identification methods. Further, inputvalues, output values, or a combination thereof might be analyzed and/orranked. For instance, in some implementations, a comparison of inputvalues might be performed and used to rank various transformation tools,while in other implementations, a comparison of output values might beperformed and used to rank various transformation tools. In comparingoutput values, the tool output examples, or patterns associatedtherewith, might be compared to the example output values provided by auser. In another case, output values can be generated using atransformation function and, thereafter, compared to the calling outputexamples.

Although example values are generally described above for use inidentifying and/or ranking relevant transformation tools, as can beappreciated, alternative or additional data or annotations can be usedto identify and/or rank transformation tools. For instance, priortransformation queries and utilized transformation tools can bemonitored and used to improve tool rankings. Such prior queries andutilized transformation tools can be specific to a user, a specificgroup of users (e.g., users within an enterprise), or any user of thetransformation engine, etc. As another example, transformation toolsspecific to an enterprise can be ranked, or weighted when ranked. As yetanother example, additional tool attributes might be used to ranktransformation tools. For example, a more frequently accessed or usedtransformation function may be weighted higher resulting in a higherranking.

Upon identifying a transformation tool(s) deemed relevant to a desireddata transformation, the transformation program generator 606 cangenerate a transformation program(s) using the transformation tool(s).As described, a transformation program is a program that can be used toperform a data transformation. Accordingly, transformation programs aregenerated that take input and can generate the desired output, asindicated by the example output values. As can be appreciated, thetransformation program generator 606 may generate transformationprograms for particular transformation tools, such as a set of highestranked transformation tool. The specific set of highest rankedtransformation tools can be determined in any manner. As one example,syntactic distances exceeding threshold (similarity threshold) may bedesignated as a high ranked transformation tool and, as such, used togenerate a transformation program.

To generate a transformation program that utilizes a transformation toolto transform data, output generated from use of the transformation toolcan be compared to the desired output (e.g., via the example outputvalues) in order to determine additional transformations required toresult in the desired output. In this regard, a transformation tool canbe executed in accordance with one or more of the example input values.For instance, relevant transformation tools may be executed using theexample input values for which corresponding example output values areprovided.

As such, for each transformation tool, such as a transformationfunction, the transformation tool is executed with example input valuesto provide transformed data results. In some cases, the resultingtransformed data is the desired transformed output. In such cases, thetransformation tool can be provided as a transformation program.Generally, however, the resulting output will vary in some form from thedesired data transformation. Accordingly, the transformation programgenerator 606 is used to generate a transformation program thatsupplements the transformation tool to arrive at the desired transformedoutput. In this regard, the transformation program generator 606 canexecute a transformation tool with one or more example input values, andtake the transformed output of that transformation tool to construct aprogram that provides the actual example output value provided, forinstance, by the user. In executing a transformation tool, multiplecolumns of data might be generated and selectively used to generate adesired output.

By way of example only, assume that a date/time function is deemedrelevant to a desired transformation. In such a case, the transformationprogram generator 606 can call the function with one or more exampleinput values and obtain the resulting transformed output. For instance,the function can be called and generate ten outputs from each of the tenexample input values. The resulting outputs can then be used todetermine how to transform the resulting output into the exampleoutput(s) value, for instance, provided by a user.

As can be appreciated, various transformations may be required toachieve a desired transformed output. Accordingly, a supplementaltransformation tool can be identified or generated and used inconnection with the initial transformation tool to generate atransformation program. For instance, transformation operators can beused on top of a transformation function to generate a transformationprogram. Transformation operators can include, for instance, reorderingoperators, splitting operators (e.g., into substrings), concatenationoperators (e.g., aggregating from different columns or fields), or otheroperators performing other syntax modifications, etc. By way of example,transformation operators can transform a full name to a desired firstinitial of first name, transform a full name into a first initial pluslast name, split a full name based on a delimiter, such as space, or thelike. Based on various transformation operators, the transformationprogram generator 606 can determine if there is a way to execute andgenerate exact output desired by the user.

In addition to using transformation operators to derive desired output,other supplemental transformation tools might be used. For example, afunction or table might be referenced and used along with an initiallyidentified transformation tool to generate a transformation program thatappropriately transforms data. For instance, a mapping table might beidentified and used along with an initially identified function to builda transformation program that can assist with syntactical composition.By way of example, if an example input value is state of Washington andWA is desired, a web table might be identified for use in transformingWashington into WA as output. Accordingly, mapping tables can be appliedon top of a transformation function, or other original transformationtool, to generate a transformation program that results in a desiredoutput. As another example, a sequence of function calls can be employedto arrive at a desired output. In this regard, a related functionattributed can be used to determine likely chains of function calls orways to complete parameters for function calls where additionalparameter values are needed.

In one implementation, various supplemental transformation tools can beanalyzed to efficiently arrive at the desired transformed output. Forexample, assume a transformation function is identified as relevant to adesired data transformation. Further assume that a transformationprogram can be generated using the transformation function and a firstsupplemental tool or using the transformation function and a secondsupplemental tool. As opposed to generating two separate transformationprograms associated with the initial transformation function, thevarious supplemental transformation tools might be analyzed to determinewhich transformation program would operate more efficiently.

In one embodiment, to determine which supplemental transformationtool(s) might result in generation of a more efficient transformationprogram, a variety of supplemental transformation tools can be analyzedas providing transformations supplemental to the initial transformationtool. For instance, each supplemental transformation tool, orsupplemental transformation tools identified as relevant, can be appliedsupplemental to an initially identified transformation tool. The outputresulting from the various supplemental transformation tools can becompared to a desired output (e.g., example output value) to identify apartial match or partial match score. The partial match score indicatesa measure of progress that each supplemental transformation tools addsto the initial transformation tool in terms of arriving at the desiredoutput. Stated differently, the partial match score indicates a measurebetween a desired output and the intermediate output generated using theparticular supplemental transformation tool. As such, rather thanattempting every possible supplemental tool combination, this methodconsiders an intermediate output. After the first level of supplementaltransformation tools are analyzed and partial match scores aregenerated, the supplemental transformation tool associated with agreatest or highest match score, or otherwise indicating an outputclosest to the desired result, can be used. This process can beiteratively performed until the desired output is generated. In thisregard, assume that a data split operator is determined as generatingintermediate output that is most similar to the desired output. In sucha case, an initial transformation tool and the data split operator canbe used to analyze various second supplemental transformation tools thatcan be used. As can be appreciated, a partial match score can bedetermined in any number of manners, such as, for example, quantity ofmatching characters, portion of matching characters, overall length ofthe input that matches, etc.

Upon generating transformation programs, the transformation programs canbe ranked, via transformation program ranker 608, in implementationsthat multiple transformation programs are generated. Transformationprogram ranker 608 can utilize any number or type of factors to rank thetransformation programs. The transformation program ranker 608 may usevarious annotations, such as tool attributes, to rank the transformationprograms. By way of example only, program ranking factors might includecomplexity of the transformation program, length of the transformationprogram (e.g., a minimum description length), execution speed,transformation tool usage, transformation tool popularity, latency,success rate, etc. In embodiments, the program ranker might incorporateprevious tool rankings, or disregard previous tool rankings.

The transformation provider 610 is generally configured to output datarelated to performing data transformations. In this way, thetransformation provider 610 might provide transformation output 612 inthe form of transformation program suggestions 614 and/or transformedoutput 616 using one or more transformation programs. By way of example,assume that a set of transformation programs are generated based onreceived example input and output values designated by a user. Upongenerating the transformation programs, transformation programsuggestions indicating or representing the transformation programs canbe provided to the user device for display to the user. A user can thenselect a transformation program to obtain transformed output results, ora preview thereof. As can be appreciated, the transformation programsuggestions may be provided for particular transformation programs, suchas a set of highest ranked transformation programs. The specific set ofhighest ranked transformation programs can be determined in any manner.As one example, a ranking exceeding threshold may be designated as ahigh ranked transformation program and, as such, used to provide atransformation program suggestion.

As another example, a transformation program can be automaticallyinitiated (e.g. without a user selection of a transformation program).For instance, a highest ranking transformation program might be executedwith transformed output results being provided to the user device fordisplay to the user. As can be appreciated, transformation programsmight be executed at a user device or at a transformation engine (orotherwise remote from the user device). For instance, after atransformation program is selected by a user, in some implementations,the user device can execute the transformation program. In otherimplementations, an indication of the selected transformation programcan be provided to the transformation engine to execute thetransformation program with transformed output being returned to theuser device for display to the user.

Exemplary Data Transformation Implementations

As described, various implementations can be used in accordance withembodiments of the present invention. FIGS. 3 and 7-9 illustrateexemplary user interfaces for implementing data transformations. FIG. 3illustrates an example user interface 300 associated with a datatransformation. Column A 310 represents various formats of dates onwhich particular transactions occurred. To perform a data transformationin accordance with embodiments of the present invention, assume a usercreates a new column B 312 adjacent to the various date formats. Furtherassume that the user enters or inputs two sample outputs in a desiredformat, example output value 314 and example output value 316. Uponselecting the dates provided in column 310, the example output values314 and 316, and the “go” button 318, various transformation programscan be generated using the example input values of column A 310 andexample output values 314 and 316. In some embodiments, the exampleinput and/or output values used for generating transformation programsmight be automatically identified or selected. For instance, a user mayselect the “go” button 318, and based on initiation of a datatransformation, example input and output values might be selected forproviding to a transformation engine. As shown, two composedtransformation programs are provided as suggestions 320 and 322. Suchtransformation program suggestions 320 and 322 can be represented in anymanner, such as via an indication of the underlying transformation toolused to generate the transformation program.

Now assume the user hovers over a particular transformation programsuggestion, such as transformation program suggestion 320. In such acase, a preview of transformed output values 324 can be providedcorresponding with the remaining example input values (or any or allvalues associated with example input values, such as values provided inthe same column). An indication may be provided to implement thetransformed output values 324 (e.g., selection of the transformationprogram suggestion as opposed to hovering over the suggestion, etc.). Ascan be appreciated, determination of the transformed output values canbe made using the selected transformation program via a user device, ora remote device (e.g., a transformation engine running remote from theuser device). Further, in some cases, the source code of the composedtransformation program is available, or can be provided, to a user suchthat the user can review and/or modify the source code. For example, auser may select a transformation program suggestion, such astransformation program 326, to view and/or modify the source code.

Turning now to FIG. 7, FIG. 7 illustrates another example user interface700 associated with a data transformation. Column A 710 representsvarious formats of dates on which particular transactions occurred. Toperform a data transformation in accordance with embodiments of thepresent invention, assume a user creates a new column B 712 adjacent tothe various date formats. Further assume that the user enters or inputstwo sample outputs in a desired format, example output value 714 andexample output value 716. Upon selecting the dates provided in column710, the example output values 714 and 716, and the “transform” button718, transformed output values 724 can be generated and presented. Forexample, various transformation programs can be generated using theexample input values of column A 710 and example output values 714 and716. As previously described, in some embodiments, the example inputand/or output values used for generating transformation programs mightbe automatically identified or selected. From the transformationprograms generated, a highest ranked transformation program can beautomatically selected and used to perform a data transformationresulting in the transformed output values 724. Such a transformationprogram may be executed at the user device or remote from the userdevice.

With reference to FIGS. 8A-8B, FIG. 8A-8B illustrate another exampleuser interface 800 associated with a data transformation. Column A 810represents various formats of dates on which particular transactionsoccurred. To perform a data transformation in accordance withembodiments of the present invention, the various formats, orinconsistent formats, of dates might be automatically detected. Based onthe detection of heterogeneous formats in the column, the dates providedin column A 810 can be automatically provided to a transformation engineas example input values. In some cases, one or more of the dates canalso be designated as an example output value(s). For instance, a firstdate might be designated as an example output value. As another example,a most frequently used date format might be identified and used as anexample output value. As yet another example, a user might be promptedto designate a desired example output value (e.g., from the inputvalues). Based on the example input and output values, varioustransformation programs can be generated and presented as transformationprogram suggestions 820 and 824. A user then has an option to select oneof the transformation program suggestions to obtain a set of transformeddata. For example, assume that a user selects transformation programsuggestion 820, as illustrated in FIG. 8B, a new column B 812 may beadded to include transformed values that have a homogenous format.

With reference to FIGS. 9A-9B, FIGS. 9A-9B illustrate another exampleuser interface 900 associated with a data transformation. Column A 910represents various formats of dates on which particular transactionsoccurred. To perform a data transformation in accordance withembodiments of the present invention, the various formats, orinconsistent formats, of dates might be automatically detected. Based onthe detection of heterogeneous formats in the column, the dates providedin column A 910 can be automatically provided to a transformation engineas example input values. In some cases, one or more of the dates canalso be designated as an example output value(s). For instance, a firstdate might be designated as an example output value. As another example,a most frequently used date format might be identified and used as anexample output value. Based on the example input and output values,various transformation programs can be generated. A highest rankedtransformation program can be automatically selected and used to performa data transformation resulting in the transformed output values 924. Asillustrated in FIG. 9B, a column B 912 with the transformed outputvalues 924 can be automatically generated and provided. Execution of atransformation program may occur at the user device or remote from theuser device. As another example, transformed output values can besuggested within the original input column. For instance, valuesidentified to be transformed can be highlighted or otherwise recognizedas a possible value to transform to another format for consistency ofdata.

FIGS. 10 and 11 provide methods of implementing data transformations ata user device. The methods 1000 and 1100 can be performed by a computerdevice, such as device 100 described previously. The flow diagramsrepresented in FIGS. 10-11 are intended to be exemplary in nature andnot limiting.

Turning initially to method 1000 of FIG. 10, at block 1002, a selectionof example input values and example output values is received. At block1004, an indication to initiate a data transformation is received.Thereafter, at block 1006, a transformation query, including theselection of example input and output values, is provided to a datatransformation service. In response, at block 1008, one or moretransformation program suggestions are received and presented to a user.Such transformation program suggestions can be generated by the datatransformation service using the example input and/or output values. Atblock 1010, a selection of one of the transformation program suggestionsis received. Based on the selection of a transformation programsuggestion, the corresponding transformation program can be executed andprovide a set of transformed output values. At block 1012, the set oftransformed output values are presented based on execution of thetransformation program corresponding with the selected transformationprogram suggestion.

Turning to method 1100 of FIG. 11, at block 1102, variance in dataformats of a set of data is detected. At block 1104, at least oneexample output value is identified. In some cases, an example outputvalue may be identified based on a position among the set of data (e.g.,a first entered value), a most frequently occurring data format, a userselection, or the like. At block 1106, the set of data having the varieddata format is provided as example input values and the identified atleast one example output value is provided as an example outputvalue(s), for example, to a transformation engine. In some cases, suchdata might be provided based on a user selection to perform a datatransformation. For example, upon detecting a variance in data formats,a user may be prompted to select whether to perform a datatransformation to result in a consistent data format. At block 1108, oneor more transformation program suggestions and/or one or moretransformed output values are received. For instance, in some cases, aset of potential transformation program suggestions might be provided tothe user device such that the user can select to preview or execute aparticular transformation program. In other cases, a set of transformedoutput values that correspond with the set of data having the varieddata formats might be received. In such a case, a transformation programmay be generated and automatically used to return the one or moretransformed output values.

FIGS. 12 and 13 provide methods of implementing data transformations,for example, at a transformation engine. The methods 1200 and 1300 canbe performed by a computer device, such as device 100 describedpreviously. The flow diagrams represented in FIGS. 12-13 are intended tobe exemplary in nature and not limiting.

Turning initially to method 1200 of FIG. 12, at block 1202, a set ofexample input values and example output values is received, for example,from a user device. At block 1204, one or more transformation programsare generated. As described herein, transformation programs can begenerated in any number of ways. Generally, transformation programs aregenerated at least using a preexisting transformation tool identified asrelevant to the desired data transformation, as indicated in the exampleinput and output values. At block 1206, a set of one or moretransformation program suggestions are provided that correspond with orrepresent at least one generated transformation program. Thereafter, atblock 1208, a selection of a transformation program suggestion isreceived. For example, a user presented with transformation programsuggestions may select one of the suggestions to initiate execution ofthe corresponding transformation program. Based on the selectedtransformation program suggestion, at block 1210, the correspondingtransformation program can be executed to generate transformed outputvalues. Such transformed output values are provided, as indicated atblock 1212. For instance, the transformed output values can be providedto a user device requesting a data transformation. As can beappreciated, in some embodiments, a user device might execute atransformation program. In such a case, the transformed output valuesare generated and provided at the user device. Further, in such anembodiment, the program code for the transformation program can beprovided to the user device so that the user device can execute theprogram.

Turning to method 1300 of FIG. 13, initially, at block 1302, a set ofexample input values and example output values is received, for example,from a user device. At block 1304, one or more transformation programsare generated and ranked. As described herein, transformation programscan be generated in any number of ways. Generally, transformationprograms are generated at least using a preexisting transformation toolidentified as relevant to the desired data transformation, as indicatedin the example input and output values. At block 1306, a transformationprogram with a highest rank is selected. Subsequently, at block 1308,the selected transformation program is executed in association with theexample input values to generate transformed output values. At block1310, the transformed output values are provided, for instance to a userdevice providing the example input values. As can be appreciated, insome embodiments, a user device might execute a transformation program.In such a case, the program code for the transformation program can beprovided to the user device for subsequent execution of thetransformation program.

Exemplary Transformation Tool Collection Implementations

As described, various transformation tool collecting implementations canbe used in accordance with embodiments of the present invention. FIGS.14-16 provide exemplary methods of implementing transformation toolcollection or acquisition, in accordance with various embodiments of thepresent invention. The methods 1400, 1500, and 1600 can be performed bya computer device, such as device 100 described previously. The flowdiagrams represented in FIGS. 14-16 are intended to be exemplary innature and not limiting.

Turning initially to FIG. 14, FIG. 14 provides a method 1400 forcollecting transformation tools. At block 1402, a plurality of sources(e.g., web sources) is crawled to identify candidate transformationtools that might be relevant for performing a data transformation. Atblock 1404, each candidate transformation tool is analyzed to determinewhether the transformation tool is in a form that can be used to performa data transformation. If so, at block 1406, a representation of thecandidate transformation tool is stored for subsequent use. Arepresentation of the candidate transformation tool might be thetransformation tool, a source, or portion thereof, associated with thetransformation tool, a reference to the transformation tool, or thelike. If, however, a candidate transformation tool is not in a form thatcan be used to perform a data transformation, the candidatetransformation tool is analyzed to determine whether the candidatetransformation tool can be used to generate a transformation tool thatcan be used to perform a data transformation. This is indicated at block1408. For example, source code can be analyzed to determine how togenerate compilable code from code otherwise deemed non-compilable.

Turning now to FIG. 15, FIG. 15 provides a method 1500 for generatingtransformation tools. Initially, at block 1502, source code that mightbe relevant for performing a data transformation is identified. At block1504, the source code is analyzed. In accordance with the analysis ofthe source code, at block 1506, a function is identified that is void ofan initial parameter, but includes a constant(s). Thereafter, at block1508, a new function is generated by identifying the constant andimplementing the constant as a parameter to the function. At block 1510,the new function is stored.

FIG. 16 provides another example method 1600 for generatingtransformation tools. Initially, at block 1602, source code that mightbe relevant for performing a data transformation is identified. At block1604, the source code is analyzed. In accordance with analyzing thesource code, at block 1606, it is determined whether the source codeincludes multiple functions that can be combined to generate a newtransformation function that can perform data transformation. If so, anew transformation function is generated using the multiple functionsincluded in the source code, as indicated at block 1608. If not, it isdetermined whether the source code includes a function that can besplit, or partially used, to generate a new transformation function thatcan be used to perform data transformation. This is indicated at block1610. If so, a new transformation function is generated using a portionof the function, as indicated at block 1612. If not, the method ends atblock 1614. At block 1616, any new transformation functions are stored.

Exemplary Transformation Tool Annotation Implementations

As described, various transformation tool annotating implementations canbe used in accordance with embodiments of the present invention. FIGS.17-19 provide exemplary methods of implementing transformation toolannotation, in accordance with various embodiments of the presentinvention. The methods 1700, 1800, and 1900 can be performed by acomputer device, such as device 100 described previously. The flowdiagrams represented in FIGS. 17-19 are intended to be exemplary innature and not limiting.

Turning initially to FIG. 17, FIG. 17 provides a method 1700 forannotating transformation tools. Initially, at block 1702, atransformation tool is analyzed. The transformation tool can be analyzedin any manner, such as, for instance, via static analysis and/or dynamicanalysis. At block 1704, one or more calling examples associated withthe transformation tool are identified. Such calling examples mayinclude calling input examples and/or calling output examples. At block1706, one or more tool attributes associated with the transformationtool are identified. Tool attributes may describe or characterize thetransformation tool, or source corresponding with the transformationtool. Such tool attributes might include, for example, tool popularity,tool usage, tool author, tool complexity, tool relationships, toolpatterns, or the like. At block 1708, the calling examples and toolattributes are stored in association with the transformation tool.

With reference to FIG. 18, FIG. 18 provides a method 1800 for annotatingtransformation tools via static analysis, in accordance with embodimentsof the present invention. Initially, at block 1802, source codeassociated with a transformation function is inspected. At block 1804,the source code is parsed into an abstract syntax tree having aplurality of fields. At block 1806, constants used in association withthe transformation function are identified. Thereafter, at block 1808,the constants are designated as input calling examples associated withthe transformation function.

FIG. 19 provides a method 1900 for annotating transformation tools viadynamic analysis, in accordance with embodiments of the presentinvention. Initially, at block 1902, source code associated with atransformation function is modified to include logging code. Suchlogging code can be used to log arguments passed into a transformationfunction. At block 1904, the source code is executed. Thereafter, atblock 1906, the logging code is used to identify an argument used by thetransformation function. At block 1908, the argument is designated as aninput calling example associated with the transformation function.

Exemplary Data Indexing Implementations

As described, various data indexing implementations can be used inaccordance with embodiments of the present invention. FIGS. 20-21provide exemplary methods of implementing data indexing, in accordancewith various embodiments of the present invention. The methods 2000 and2100 can be performed by a computer device, such as device 100 describedpreviously. The flow diagrams represented in FIGS. 20 and 21 areintended to be exemplary in nature and not limiting.

Turning initially to FIG. 20, FIG. 20 provides a method 2000 forgenerating an index, in accordance with embodiments of the presentinvention. Initially, at block 2002, tool examples associated with atransformation tool are referenced. At block 2004, one or more toolexamples are associated with a transformation tool to generate an index.Tool examples may include calling input examples and/or calling outputexamples. At block 2006, tool patterns are generated for each of the oneor more tool examples. At block 2008, redundant tool patterns can beidentified. Thereafter, at block 2010, tool examples associated with theredundant tool patterns can be removed from the index. At block 2012,the compressed index is used to search for relevant transformationtools. As can be appreciated, in some embodiments, an index may includenumerous transformation tools and corresponding tool examples. Further,in another implementation, tool patterns can be generated and used toremove redundancy prior to generating the index.

With reference to FIG. 21, FIG. 21 provides a method 2100 for generatingan index, in accordance with embodiments of the present invention.Initially, at block 2102, tool examples associated with a transformationtool are referenced. At block 2104, tool patterns are generated for thetool examples. At block 2106, redundant tool patterns are identified.Tool patterns may be considered redundant if the same or similar withina threshold of similarity. At block 2108, the redundant tool patternscan be discarded. Thereafter, at block 2110, the remaining tool patternsare associated with the transformation tool to generate an index. As canbe appreciated, in some embodiments, an index may include numeroustransformation tools and corresponding tool patterns. Further, inanother implementation, tool patterns can be generated and used toremove redundancy after generating the index.

Exemplary Transformation Program Generation Implementations

As described, various transformation program generating implementationscan be used in accordance with embodiments of the present invention.FIGS. 22-25 provide exemplary methods of implementing transformationprogram generation, in accordance with various embodiments of thepresent invention. The methods 2200, 2300, 2400, and 2500 can beperformed by a computer device, such as device 100 described previously.The flow diagrams represented in FIGS. 22-25 are intended to beexemplary in nature and not limiting.

Turning initially to FIG. 22, FIG. 22 provides a method 2200 forgenerating and providing transformation programs, in accordance withembodiments of the present invention. Initially, at block 2202, a set ofexample values are received. In embodiments, example values, such asexample input values and example output values, can be received from auser device, for example, based on a user indication. At block 2204,transformation tools that are relevant to the example values, ortransformation associated therewith, are identified. Any number ofmanners can be used to identify relevant transformation tools. Forinstance, a comparison of example values to tool examples (e.g., callingexamples) can be used. As another example, a comparison of example valuepatterns to tool patterns can be used. At block 2206, the transformationtools are ranked. For instance, transformation tools can be ranked basedon syntactic distance associated with the comparison of example valuesand tool values, or patterns associated therewith. At block 2208, a setof highest ranked transformation tools are selected. For each of theselected transformation tools, the transformation tools are executedusing example input values to generate a set of initial output values.This is indicated at block 2210. Based on a comparison between theinitial output values and the example output values, a supplementaltransformation tool is identified or determined for use in generating atransformation program that can perform a desired data transformation.This is indicated at block 2212. Although FIG. 22. describes use of asupplemental transformation tool, as can be appreciated, any number oftransformation tools can supplement an initial transformation tool used.For example, in one embodiment, functions, tables, and/or operators canbe used together as multiple supplemental transformation tools or asingle supplemental transformation tool. Similarly, an initialtransformation tool can include any combination of tools, such asfunctions, tables, and/or operators, used to perform complextransformations. At block 2214, a transformation program is generatedfor each selected transformation tool. Thereafter, at block 2216, thetransformation programs are ranked. One or more of the rankedtransformation programs are provided as transformation programsuggestions or used to generate transformed data, as indicated at block2218.

With reference to FIG. 23, FIG. 23 provides a method 2300 for generatingand providing transformation programs using transformation functions, inaccordance with embodiments of the present invention. Initially, atblock 2302, a set of example input and output values are received. Inembodiments, example values can be received from a user device, forexample, based on a user indication. At block 2304, transformationfunctions are searched to identify transformation functions associatedwith calling input examples that correspond (match or are similar to,for instance, within a similarity threshold) with one or more exampleinput values. At block 2306, the identified transformation functions areranked based on the correspondence of the calling input examples withthe example input values. As can be appreciated, a comparison of outputcan additionally or alternatively be used to identify and/or rankrelevant transformation functions. For instance, transformationfunctions can be ranked based on syntactic distance associated with thecomparison of example values and calling examples, or patternsassociated therewith. At block 2308, a set of highest rankedtransformation functions are selected. For each of the selectedtransformation functions, the transformation functions are executedusing the example input values to generate a set of initial outputvalues. This is indicated at block 2310. Based on a comparison betweenthe initial output values and the example output values, a supplementaltransformation tool is identified or determined for use in generating atransformation program that can perform a desired data transformation.This is indicated at block 2312. Such a supplemental transformation toolmay be a table tool, an operator tool, a service tool, a combinationthereof, or the like. At block 2314, a transformation program isgenerated for each selected transformation tool using the supplementaltransformation tool. Thereafter, at block 2316, the transformationprograms are ranked. Such transformation programs can be ranked, forexample, using tool attributes, such as the function popularity,function author, etc. One or more of the ranked transformation programsare provided as a transformation program suggestion(s) or used togenerate transformed data, as indicated at block 2318.

Turning to FIG. 24, FIG. 24 provides one example of a method foridentifying relevant transformation tools using syntactic distance, inaccordance with embodiments of the present invention. Initially, atblock 2402, an example value is received. At block 2404, a tool exampleis referenced. A tool example can be, for instance, a calling inputexample associated with a function. At block 2406, the example value andthe tool example are converted to respective patterns that syntacticallyrepresent the example value and the tool example. As can be appreciated,although both the example value and tool example are described as beingconverted to patterns, in some cases, only the tool example or theexample value might be converted to a pattern and used for a comparison.At block 2408, the example value pattern and the tool example patternare compared to one another. Based on the comparison, at block 2410, asyntactic distance is generated that indicates an extent of syntacticaldistance between the patterns. At block 2412, the syntactic distance isused to rank the tool associated with the tool example. The rankedtransformation tools can then be used to select a transformation tool togenerate a transformation program.

Now with reference to FIG. 25, FIG. 25 provides one example of a methodfor efficiently generating a transformation program, in accordance withembodiments of the present invention. Initially, at block 2502, atransformation function that is relevant to a desired datatransformation is identified. Any manner of analysis may be performed toidentify a relevant transformation function. At block 2504, thetransformation function is executed with an example input value (e.g.,provided by a user) to obtain an initial output value. At block 2506, aplurality of supplemental transformation tools are applied to theinitial output value to generate a plurality of intermediary outputvalues. Such supplemental transformation tools may include varioustables, operators, and/or web services. At block 2508, each of theintermediary output values are compared to an example output valueassociated with the example input value. Based on the comparisons, atblock 2510, a partial match score is generated for each intermediaryoutput value in accordance with the extent of similarity (ordifferences) between the intermediary output values and the exampleoutput value. At block 2512, it is determined whether the intermediaryoutput value associated with the greatest partial match score is withina threshold of similarity to example output value. For example, apartial match score exceeding a similarity threshold may be used todetermine that the intermediary output value matches or corresponds withthe example output value. If so, the transformation function and thesupplemental transformation tool producing the intermediary output valuecorresponding with the greatest partial match score are used to generatea transformation program, as indicated at block 2514. On the other hand,if not, a plurality of supplemental transformation tools are applied tothe intermediary output value to generate another level of intermediaryoutput values. This is shown at block 2516. Thereafter, the method caniteratively repeat blocks 2508-2516 until a determination is made thatthe intermediary output value associated with the greatest partial matchscore is within a threshold of similarity to the example output valueand a transformation program is generated in association therewith.

Exemplary Extensible Data Transformation Implementations

As described, various extensible data transformation implementations canbe used in accordance with embodiments of the present invention. FIGS.26-27 provide exemplary methods of implementing extensible datatransformations, in accordance with various embodiments of the presentinvention. The methods 2600 and 2700 can be performed by a computerdevice, such as device 100 described previously. The flow diagramsrepresented in FIGS. 26-27 are intended to be exemplary in nature andnot limiting.

Turning initially to FIG. 26, FIG. 26 provides a method 2600 forfacilitating extensible data transformations, in accordance withembodiments of the present invention. Initially, at block 2602, a newtransformation tool is received from a user of a transformation service.At block 2604, the new transformation tool is annotated and stored.Subsequently, at block 2606, a set of example values, such as exampleinput and output values, are received. As can be appreciated, the set ofexample values can be received by the same user that provided the newtransformation tool or another user of the transformation service. Atblock 2608, the new transformation tool is searched among othertransformation tools to identify one or more transformation toolsrelevant to a data transformation associated with the received set ofexample values. At block 2610, the new transformation tool is selectedas relevant to the data transformation. Thereafter, at block 2612, thenew transformation tool is used to generate a transformation program.The transformation program is executed at block 2614 to producetransformed output values. In some cases, the transformation programmight be provided as a suggestion, and upon selection, produce thetransformed output values. At block 2616, the set of example valuesand/or the transformed output values are annotated in accordance withthe new transformation tool. Such annotations can be used for subsequentanalysis of the new transformation tool provided by the user.

With reference to FIG. 27, FIG. 27 provides a method 2700 forfacilitating extensible data transformations, in accordance withembodiments of the present invention. Initially, at block 2702, a newtransformation tool is received from an enterprise user of atransformation service. At block 2704, the new transformation tool isannotated and stored, including a security level annotation.Subsequently, at block 2706, a set of example values, such as exampleinput and output values, are received. As can be appreciated, the set ofexample values can be received by the same user that provided the newtransformation tool or another user of the transformation service. Atblock 2708, it is determined if the security level associated with thenew transformation tool permits the new transformation tool to beutilized in connection with the received set of example values. If so,the new transformation tool is searched among other transformation toolsto identify one or more transformation tools relevant to a datatransformation associated with the received set of example values. Asindicated at block 2710. If not, the new transformation tool is notsearched when identifying one or more transformation tools relevant to adata transformation associated with the received set of example values,as shown at block 2712.

The technology described herein has been described in relation toparticular aspects, which are intended in all respects to beillustrative rather than restrictive.

What is claimed is:
 1. A computing system comprising: a processor; andcomputer storage memory having computer-executable instructions storedthereon which, when executed by the processor, configure the computingsystem to facilitate data transformations using a set of example valuesincluding one or more example input values that indicate data values tobe transformed and one or more example output values that indicate adesired form in which to transform data, the computing system configuredto: search a plurality of remote sources to identify candidatetransformation tools relevant for performing data transformations;analyze the candidate transformation tools to identify one or more toolexamples corresponding with each of the candidate transformation tools;for each of the candidate transformation tools, store the one or moretool examples in association with the corresponding candidatetransformation tool; and based on a comparison of at least a portion ofthe tool examples with at least a portion of the set of example values,identify a transformation tool as relevant to facilitate transformingthe one or more example input values to the desired form in which totransform data.
 2. The computing system of claim 1, wherein the remotesources comprise web sources, enterprise sources, or a combinationthereof.
 3. The computing system of claim 1, wherein the candidatetransformation tools comprise transformation functions, transformationtables, or a combination thereof.
 4. The computing system of claim 1,wherein analyzing the candidate transformation tools comprisesperforming a static analysis of transformation functions.
 5. Thecomputing system of claim 4, wherein the static analysis comprises:inspecting source code associated with the transformation functions; andfor each source code associated with a transformation function, parsingthe source code into an abstract syntax tree having a plurality offields, identifying one or more constants used in association with thetransformation function, and designating the one or more constants asinput calling examples associated with the transformation function. 6.The computing system of claim 1, wherein analyzing the candidatetransformation tools comprises performing a dynamic analysis oftransformation functions.
 7. The computing system of claim 6, whereinthe dynamic analysis comprises: modifying source code associated withthe transformation functions to include logging code; for each sourcecode associated with a transformation function, executing the sourcecode, using the logging code to identify an argument used by thetransformation function, and designating the argument as an inputcalling example associated with the transformation function.
 8. Thecomputing system of claim 1, wherein analyzing the candidatetransformation tools further comprises identifying one or more toolattributes corresponding with each of the candidate transformationtools.
 9. The computing system of claim 8, wherein the one or more toolattributes is used to identify the transformation tool as relevant. 10.A computer-implemented method for facilitating data transformations, themethod comprising: searching a plurality of remote sources to identify acandidate transformation function for performing data transformations;analyzing source code associated with the candidate transformationfunction to identify a portion of the source code for use in generatinga new transformation function; generating a new transformation function;and storing the new transformation function for subsequent use intransforming data.
 11. The method of claim 10 further comprising usingthe new transformation function to facilitate a data transformation. 12.The method of claim 10, wherein identifying the portion of the sourcecode for use in generating the new transformation function comprisesidentifying a function that includes a constant and is void of aninitial parameter.
 13. The method of claim 12, wherein generating thenew transformation function comprises implementing the constant as aparameter of the function.
 14. The method of claim 10, whereinidentifying the portion of the source code for use in generating the newtransformation function comprises identifying a first function and asecond function within the source code.
 15. The method of claim 14,wherein generating the new transformation function comprises combiningthe first function and the second function.
 16. One or more computerstorage media having computer-executable instructions embodied thereonthat, when executed by one or more processors, cause the one or moreprocessors to perform a method for facilitating data transformations,the method comprising: searching a plurality of remote sources toidentify candidate transformation tools relevant for performing datatransformations; analyzing the candidate transformation tools toidentify one or more tool examples corresponding with each of thecandidate transformation tools; analyzing the candidate transformationtools to identify one or more tool attributes corresponding with each ofthe candidate transformation tools; for each of the candidatetransformation tools, storing the one or more tool examples and the oneor more tool attributes in association with the corresponding candidatetransformation tool.
 17. The media of claim 16, wherein the one or moretool attributes comprise one or more of tool relationships, toolpopularity, tool usage, tool author, and tool difficulty.
 18. The mediaof claim 16 further comprising generating an index using the one or moretool examples and the one or more tool attributes.
 19. The media ofclaim 16, wherein the remote sources comprise web sources, enterprisesources, or a combination thereof.
 20. The media of claim 16, whereinthe candidate transformation tools comprise transformation functions,and analyzing the candidate transformation tools to identify one or moretool examples corresponding with each of the candidate transformationtools comprises performing a static analysis or a dynamic analysis inassociation with the transformation functions.